CN223028364U - Air hammer with turnover assembly for forging piece processing - Google Patents

Abstract

The utility model discloses an air hammer for forging piece processing, which comprises a clamping and overturning mechanism, an electric telescopic rod and a cylinder, wherein the electric telescopic rod and the cylinder are arranged in the clamping and overturning mechanism, one side of the clamping and overturning mechanism is provided with a driving mechanism, an air hammer body and a driving motor, the air hammer body and the driving motor are arranged on one side of the driving mechanism, the clamping and overturning mechanism comprises a supporting column, the bottom end in the supporting column is fixedly connected with the electric telescopic rod, the output end of the electric telescopic rod is fixedly connected with a rack, one side of the rack is in meshed connection with a positioning block, the outer side of the positioning block is fixedly connected with the supporting column, one side of the top end of the rack is in meshed connection with a gear, the workpiece can be clamped by arranging the clamping and overturning mechanism, and the workpiece can be driven to move by arranging the driving mechanism, so that different positions of the workpiece can be forged.

Description

Air hammer with turnover assembly for forging piece processing

Technical Field

The utility model relates to the technical field of air hammers, in particular to an air hammer with a turnover assembly for forging piece processing.

Background

The air hammer is one kind of free forging equipment, and the compression cylinder compresses air, and the air is fed into the working cylinder via the distributing valve to push the piston and the hammer head to move up and down for hammering, so that the free forging machine is flexible in operation and suitable for use in various free forgings, such as extension, upsetting, punching, shearing, forge welding, torsion, bending, etc. and may be used in various open die forging with the use of cushion die.

Publication number CN216680031U discloses a forge piece processing with pneumatic hammer that has flip structure, through the cooperation of first hydraulic stem and second hydraulic stem, drive motor longitudinal movement through the second hydraulic stem, drive motor and metalwork lifting, utilize first hydraulic stem to drive metalwork lateral shifting, can realize effective forging of complicated metalwork, avoided the staff to grasp adjustment metalwork process and receive the injury easily, the pneumatic hammer can't overturn the metalwork voluntarily problem, but this patent still has following problem in the in-service use process:

Although the pneumatic hammer with the turnover structure for forging piece processing drives the motor to longitudinally move through the second hydraulic rod, and the first hydraulic rod drives the metal piece to transversely move, effective forging of complex metal pieces can be achieved, but the motor directly drives the metal piece to rotate, the turnover angle of the metal piece is not well controlled, and therefore forging efficiency of the pneumatic hammer is reduced.

An air hammer for forging processing having a turnover assembly is proposed so as to solve the problems set forth in the foregoing.

Disclosure of utility model

The utility model aims to provide an air hammer with a turnover assembly for forging piece processing, which aims to solve the problems that in the prior art, a motor is driven to longitudinally move by a second hydraulic rod, a metal piece is driven to transversely move by a first hydraulic rod, effective forging of complex metal pieces can be realized, but the metal piece is directly driven to rotate by the motor, the turnover angle of the metal piece is not well controlled, and therefore, the forging efficiency of the air hammer is reduced.

In order to achieve the aim, the utility model provides the technical scheme that the pneumatic hammer for forging piece processing with the overturning assembly comprises a clamping overturning mechanism, an electric telescopic rod and a cylinder, wherein the electric telescopic rod and the cylinder are arranged in the clamping overturning mechanism;

one side of the clamping turnover mechanism is provided with a driving mechanism, and an air hammer body and a driving motor which are arranged on one side of the driving mechanism;

Further comprises:

The clamping turnover mechanism comprises a supporting column, the bottom end inside the supporting column is fixedly connected with an electric telescopic rod, and the output end of the electric telescopic rod is fixedly connected with a rack;

One side of the rack is connected with a positioning block in a meshed manner, the outer side of the positioning block is fixedly connected with a support column, and one side of the top end of the rack is connected with a gear in a meshed manner;

The central position inside the gear is fixedly connected with a roll shaft, one end of the roll shaft is rotationally connected with the support column, and the other end of the roll shaft penetrates through the support column and is connected with a belt in a fitting mode.

Preferably, the one end laminating that the roller was kept away from to the belt is connected with the cylinder, the one end and the support column rotation of cylinder are connected, the other end fixedly connected with braced frame of cylinder.

Preferably, one side of the support column, which is close to the cylinder, is fixedly connected with the cylinder, the output end of the cylinder penetrates through the cylinder and is rotationally connected with a sliding block, and the inside of the sliding block is in sliding connection with the support frame.

Preferably, the upper and lower both ends symmetry rotation of slider is connected with first connecting rod, and two the one end rotation that the slider was kept away from to first connecting rod is connected with the clamp block, one side fixedly connected with tooth form plate of clamp block, the one end rotation that the tooth form plate was kept away from to the clamp block is connected with the second connecting rod, the one end rotation that the clamp block was kept away from to the second connecting rod is connected with the supporting shoe, one side and the braced frame fixed connection of supporting shoe.

Preferably, the driving mechanism comprises a base, one side of the top of the base is connected with the air hammer body in a fitting manner, one end of the workpiece is connected with the toothed plate in a fitting manner, and one end of the base, far away from the air hammer body, is fixedly connected with the driving motor.

Preferably, the output end of the driving motor penetrates through the base and is fixedly connected with a threaded rod, one end, far away from the driving motor, of the threaded rod is rotationally connected with the base, and the outer side of the threaded rod is in threaded connection with a threaded sleeve.

Preferably, the bottom fixedly connected with fixed cover of thread bush, the inside sliding connection of fixed cover has the guide arm, the both ends of guide arm all with base fixed connection, the top fixedly connected with bracing piece of thread bush, the top of bracing piece runs through the base and fixedly connected with elevating platform, the top and the support column fixed connection of elevating platform.

Compared with the prior art, the air hammer for forging piece processing with the overturning assembly has the advantages that the air hammer can clamp a workpiece through the arrangement of the clamping overturning mechanism, meanwhile, can overturn the workpiece, can drive the workpiece to move through the arrangement of the driving mechanism, and forges different positions of the workpiece, and the air hammer has the following specific contents:

1. The workpiece can be clamped by arranging the clamping turnover mechanism, the workpiece can be turned over at the same time, forging is carried out on different positions of the workpiece, the sliding block is driven to move outside the supporting frame through the air cylinder, so that the first connecting rod is driven to rotate around the sliding block and the clamping blocks, the clamping blocks are limited by the second connecting rod, the workpiece can be clamped by the relative movement of the two clamping blocks, the rack is driven to move up and down through the electric telescopic rod, the roller shaft is driven to rotate by utilizing the meshing effect between the rack and the gear, the cylinder and the roller shaft are driven to rotate together by utilizing the synchronous effect of the belt, and the workpiece can be turned over by driving the clamping blocks through the cylinder;

2. can drive the work piece through setting up actuating mechanism and remove, forge the different positions of work piece, drive the threaded rod through driving motor and rotate, utilize the screw thread effect between threaded rod and the thread bush to drive fixed cover and have pivoted trend, utilize the spacing effect of guide bar to fixed cover, thereby drive the bracing piece and remove along the horizontal direction of guide arm, can drive the work piece and remove, can be according to the height of the size adjustment clamp block of work piece through setting up the elevating platform, thereby improve the stability of clamp block centre gripping.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

FIG. 2 is a schematic illustration of the front cross-sectional structure of FIG. 1 in accordance with the present utility model;

FIG. 3 is an enlarged schematic view of the clamping and flipping mechanism of FIG. 2 in accordance with the present utility model;

FIG. 4 is an enlarged schematic view of the structure of FIG. 3B according to the present utility model;

FIG. 5 is a schematic view of the closed state structure of the clamping block of FIG. 4 according to the present utility model;

Fig. 6 is an enlarged schematic view of the structure of fig. 2 a according to the present utility model.

In the figure, 1, a clamping turnover mechanism, 101, a support column, 102, an electric telescopic rod, 103, a rack, 104, a positioning block, 105, a gear, 106, a roll shaft, 107, a belt, 108, a cylinder, 109, a support frame, 110, a cylinder, 111, a sliding block, 112, a first connecting rod, 113, a clamping block, 114, a tooth plate, 115, a second connecting rod, 116, a support block, 2, a driving mechanism, 201, a base, 202, an air hammer body, 203, a workpiece, 204, a driving motor, 205, a threaded rod, 206, a threaded sleeve, 207, a fixed sleeve, 208, a guide rod, 209, a support rod, 210 and a lifting platform.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-6, the utility model provides a pneumatic hammer for forging processing with a turnover assembly, which comprises a clamping turnover mechanism 1, an electric telescopic rod 102 and a cylinder 110, wherein the electric telescopic rod 102 and the cylinder 110 are arranged in the clamping turnover mechanism 1; the clamping turnover mechanism 1 comprises a support column 101, wherein the bottom end inside the support column 101 is fixedly connected with an electric telescopic rod 102, the output end of the electric telescopic rod 102 is fixedly connected with a rack 103, and the rack 103 is driven to move by the electric telescopic rod 102;

One side of the rack 103 is connected with a positioning block 104 in a meshed manner, the outer side of the positioning block 104 is fixedly connected with the support column 101, one side of the top end of the rack 103 is connected with a gear 105 in a meshed manner, and the stability of the rack 103 during movement can be improved by arranging the positioning block 104;

The center position inside the gear 105 is fixedly connected with a roll shaft 106, one end of the roll shaft 106 is rotationally connected with the support column 101, the other end of the roll shaft 106 penetrates through the support column 101 and is in fit connection with a belt 107, and both ends of the belt 107 are provided with belt pulleys, so that the belt 107 can drive the cylinder 108 to rotate;

One end of the belt 107 far away from the roll shaft 106 is connected with a cylinder 108 in an attached mode, one end of the cylinder 108 is connected with the support column 101 in a rotating mode, the other end of the cylinder 108 is fixedly connected with a support frame 109, and the position of the support frame 109 can be fixed through the arrangement of the cylinder 108;

One side of the support column 101, which is close to the cylinder 108, is fixedly connected with a cylinder 110, the output end of the cylinder 110 penetrates through the cylinder 108 and is rotationally connected with a sliding block 111, the inside of the sliding block 111 is in sliding connection with a support frame 109, a piston rod of the cylinder 110 is in penetrating connection with the support column 101, and a piston rod of the cylinder 110 is in penetrating connection with the support frame 109;

The upper end and the lower end of the sliding block 111 are symmetrically and rotatably connected with a first connecting rod 112, one end, far away from the sliding block 111, of each first connecting rod 112 is rotatably connected with a clamping block 113, one side of each clamping block 113 is fixedly connected with a toothed plate 114, one end, far away from each toothed plate 114, of each clamping block 113 is rotatably connected with a second connecting rod 115, one end, far away from each clamping block 113, of each second connecting rod 115 is rotatably connected with a supporting block 116, one side of each supporting block 116 is fixedly connected with a supporting frame 109, and friction force of each clamping block 113 can be improved by arranging the toothed plate 114;

The driving mechanism 2 comprises a base 201, one side of the top of the base 201 is connected with an air hammer body 202 in a fitting way, a workpiece 203 is connected to the surface of one side of the air hammer body 202 in a fitting way, one end of the workpiece 203 is connected with a toothed plate 114 in a fitting way, one end of the base 201, which is far away from the air hammer body 202, is fixedly connected with a driving motor 204, and a threaded rod 205 is driven to rotate by the driving motor 204;

The output end of the driving motor 204 penetrates through the base 201 and is fixedly connected with a threaded rod 205, one end, far away from the driving motor 204, of the threaded rod 205 is rotationally connected with the base 201, a threaded sleeve 206 is in threaded connection with the outer side of the threaded rod 205, and the fixed sleeve 207 is driven to rotate by utilizing the threaded effect between the threaded rod 205 and the threaded sleeve 206;

The bottom fixedly connected with fixed cover 207 of thread bush 206, the inside sliding connection of fixed cover 207 has guide arm 208, and guide arm 208's both ends all with base 201 fixed connection, the top fixedly connected with bracing piece 209 of thread bush 206, the top of bracing piece 209 runs through base 201 and fixedly connected with elevating platform 210, and elevating platform 210's top and support column 101 fixed connection can be according to the height of work piece 203's size adjustment clamp block 13 through setting up elevating platform 210 to improve the stability of clamp block 113 centre gripping.

Before the pneumatic hammer with the overturning assembly for forging piece processing is used, the whole condition of the device is required to be checked firstly to confirm that normal work can be carried out, according to the figures 1-6, the height of the clamping block 113 is firstly adjusted according to the size of the workpiece 203 to enable the clamping block to be opposite to the central axis of the workpiece 203, then the cylinder 110 is started to drive the sliding block 111 to move outside the supporting frame 109, so that the first connecting rod 112 is driven to rotate around the sliding block 111 and the clamping block 113, and the limiting of the second connecting rod 115 to the clamping block 113 is utilized to realize the relative movement of the two clamping blocks 113 to clamp the workpiece 203;

Secondly, the air hammer body 202 is started to beat the workpiece 203, when the workpiece 203 needs to be overturned, the electric telescopic rod 102 is started to drive the rack 103 to move up and down, the roller shaft 106 is driven to rotate by utilizing the meshing action between the rack 103 and the gear 105, the cylinder 108 and the roller shaft 106 are driven to rotate together by utilizing the synchronous action of the belt 107, and the clamping block 113 is driven to rotate by the cylinder 108, so that the workpiece 203 can be overturned;

Finally, when the position of the workpiece 203 needs to be changed, the driving motor 204 is started to drive the threaded rod 205 to rotate, the fixed sleeve 207 is driven to have a rotating trend by utilizing the threaded action between the threaded rod 205 and the threaded sleeve 206, and the supporting rod 209 is driven to move along the horizontal direction of the guiding rod 208 by utilizing the limiting action of the guiding rod 208 on the fixed sleeve 206, so that the workpiece 203 can be driven to move.

Although the present utility model has been described with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements and changes may be made without departing from the spirit and principles of the present utility model.

Claims (7)

1. An air hammer for forging workpiece processing with a turnover assembly, comprising a clamping and turnover mechanism (1), and an electric telescopic rod (102) installed inside the clamping and turnover mechanism (1) and a cylinder (110) on the top surface; A driving mechanism (2) is provided on one side of the clamping and flipping mechanism (1), and an air hammer body (202) and a driving motor (204) are installed on one side of the driving mechanism (2); It is characterized by further comprising: The clamping and flipping mechanism (1) comprises a support column (101), the bottom end inside the support column (101) is fixedly connected to an electric telescopic rod (102), and the output end of the electric telescopic rod (102) is fixedly connected to a rack (103); One side of the rack (103) is meshedly connected with a positioning block (104), the outer side of the positioning block (104) is fixedly connected to the support column (101), and one side of the top end of the rack (103) is meshedly connected with a gear (105); A roller shaft (106) is fixedly connected to the center position inside the gear (105), one end of the roller shaft (106) is rotatably connected to the support column (101), and the other end of the roller shaft (106) passes through the support column (101) and is closely connected to a belt (107). 2. An air hammer for forging parts processing with a flip assembly according to claim 1, characterized in that: one end of the belt (107) away from the roller (106) is fittedly connected to a cylinder (108), one end of the cylinder (108) is rotatably connected to the support column (101), and the other end of the cylinder (108) is fixedly connected to a support frame (109). 3. An air hammer for forging parts processing with a flip assembly according to claim 2, characterized in that: the side of the support column (101) close to the cylinder (108) is fixedly connected to the cylinder (110), the output end of the cylinder (110) passes through the cylinder (108) and is rotatably connected to a slider (111), and the interior of the slider (111) is slidably connected to the support frame (109). 4. An air hammer for forging parts processing with a flip assembly according to claim 3, characterized in that: the upper and lower ends of the slider (111) are symmetrically rotatably connected with the first connecting rods (112), the ends of the two first connecting rods (112) away from the slider (111) are rotatably connected with the clamping blocks (113), one side of the clamping blocks (113) is fixedly connected with a toothed plate (114), the end of the clamping block (113) away from the toothed plate (114) is rotatably connected with the second connecting rod (115), the end of the second connecting rod (115) away from the clamping block (113) is rotatably connected with the support block (116), and one side of the support block (116) is fixedly connected to the support frame (109). 5. An air hammer for forging workpiece processing with a turnover assembly according to claim 1, characterized in that: the driving mechanism (2) comprises a base (201), one side of the top of the base (201) is connected to the air hammer body (202), a workpiece (203) is fitted and connected to the surface of one side of the air hammer body (202), one end of the workpiece (203) is fitted and connected to the toothed plate (114), and one end of the base (201) away from the air hammer body (202) is fixedly connected to the driving motor (204). 6. An air hammer for forging parts processing with a flip assembly according to claim 5, characterized in that: the output end of the driving motor (204) passes through the base (201) and is fixedly connected to a threaded rod (205), one end of the threaded rod (205) away from the driving motor (204) is rotatably connected to the base (201), and the outer side of the threaded rod (205) is threadedly connected to a threaded sleeve (206). 7. An air hammer for forging parts processing with a flip assembly according to claim 6, characterized in that: the bottom end of the threaded sleeve (206) is fixedly connected to a fixed sleeve (207), the interior of the fixed sleeve (207) is slidably connected to a guide rod (208), both ends of the guide rod (208) are fixedly connected to the base (201), the top end of the threaded sleeve (206) is fixedly connected to a support rod (209), the top end of the support rod (209) passes through the base (201) and is fixedly connected to a lifting platform (210), and the top of the lifting platform (210) is fixedly connected to the support column (101).